it will get smaller
Ideal gas law PV=nRT
or Charles Law V/T = k
T= temperature
V= volume
keep everything else constant, V and T are directly proportional. This means that if V increases so will T. If V decreases, T will get smaller.
The volume of a gas - at constant pressure - is proportional to the absolute temperature, that is, to the temperature expressed in Kelvin. This relationship is only approximate for real gases, but it is close enough for most practical purposes.
When gas is cooled, its particles lose energy and move more slowly, ultimately leading to a decrease in temperature and a decrease in volume if the gas is kept at constant pressure. This process is known as cooling or refrigeration.
The gas takes on the size and shape of the container it's in. So if you make the volume of the container smaller (compress it) the volume of the gas is smaller as well. However, this comes at a higher pressure exerted, so there is no spontaneous mass creation.Well, by definition, compress means "to make smaller; to press or squeeze together; or to make something occupy a smaller space or volume." Therefore, the very word "compress" implies a decrease in volume. So if you wanted to know what happens when you compress a gas, you are squeezing it into a smaller space, or decreasing the volume.If you were to let the gas maintain a constant temperature as you compress it, then pressure would increase. If you were to let the gas maintain a constant pressure, then temperature would decrease.If you were to rephrase your question to "what happens to the volume of gas if put under pressure," then the gas' volume would decrease. For the temperature to remain constant and the pressure to increase, a gas must decrease in volume to occupy a smaller area.
If you shrink the container containing gas, the volume of the gas decreases because the gas particles are forced into a smaller space. This increase in pressure due to the reduced volume is described by Boyle's Law.
Butane gas is compressible. It can be compressed into a smaller volume at higher pressures.
The Ideal Gas Laws describe the relationship of temperature, pressure, and volume for a gas. These three things are all related. At lower temperatures a gas will exert lower pressure if the volume remains the same, or can exert the same pressure but in a smaller volume.
When a balloon is cooled, the air inside it contracts and takes up less space, causing the balloon to shrink. This is because the volume of a gas decreases as its temperature decreases, following the ideal gas law.
No, gas contracts or decreases in volume when cooled because the molecules lose kinetic energy and move closer together. This decrease in volume causes the gas to contract and take up less space.
If you cool a gas then its volume shrinks. As the container is expand/contactable, the container will also shrink.
When any gas (or gas mixture), including air, is cooled, the molecules will move slower and they will be able to be closer together. The volume needed to store a certain amount of gas will be less. If you cool it enough, it will eventually turn into a liquid.
The volume of a gas - at constant pressure - is proportional to the absolute temperature, that is, to the temperature expressed in Kelvin. This relationship is only approximate for real gases, but it is close enough for most practical purposes.
The volume of a gas cylinder refers to the amount of space inside the cylinder that can hold gas. A larger volume means the cylinder can store more gas, while a smaller volume means it can store less gas. The volume of a gas cylinder directly affects its storage capacity, with a larger volume allowing for more gas to be stored and a smaller volume limiting the amount of gas that can be stored.
The volume decreases (smaller,less)
57.3ml
When a gas is cooled, the molecules lose kinetic energy, resulting in fewer collisions with each other. This decrease in collisions leads to a reduction in pressure, volume, and temperature of the gas.
Yes, particles in a gas can be compressed into a smaller volume by reducing the space between them. This will increase the pressure of the gas as the particles are forced closer together.
Oxygen gas in a syringe can be compressed to a smaller volume because gases are highly compressible compared to liquids and solids. When the volume of the syringe is reduced, the gas molecules are forced closer together, leading to an increase in pressure and a decrease in volume.